10.7907/4KV8-F830
Zhang, Juner
Juner
Zhang
0000-0001-8181-1187
California Institute of Technology
New-to-Nature Selective C-H Alkylation Using Engineered Carbene Transferases
California Institute of Technology
2022
Dissertation
directed evolution
carbene
protein engineering
biocatalysis
C-C bond formation
Chemistry
cytochromes P450
C–H functionalization
2022-06-02
English
14558
PDF
Final
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Synthetic methods to selectively convert C–H bonds, a prevalent motif in organic molecules, into functionalities can significantly accelerate the syntheses and derivatization of molecules. In the past decade, many enzymatic catalysts have emerged as greener, more selective, and more versatile alternatives to small-molecule catalysts for selective C–H functionalization reactions. In nature, enzymes only catalyze a limited set of C–H functionalization reactions that are useful for chemical synthesis, as the overwhelming majority of known C–H functionalization enzymes in nature are hydroxylases. The diversity of the enzymatic reaction scope needs to be substantially expanded to make them broadly useful to synthetic chemists. This thesis will describe new enzymes, which we repurposed from one of the most prevalent C–H hydroxylases in nature, cytochromes P450, which are now able to catalyze new-to-nature C–H alkylation reactions via selective carbene transfer. Given the central role of C–C bond forming reactions in building and elaborating the carbon skeleton of organic molecules, these transformations are of high interest in many fields of research, such as medicinal chemistry and material chemistry. In Chapter 1, I review a recent surge in newly identified enzymes, repurposed enzymes, and artificial metalloenzymes which can catalyze selective C–H functionalization reactions. Chapter 2 details the development of a panel of enantiodivergent α-amino C(sp³)−H fluoroalkylases. Using directed evolution, the carbene transferases can install fluoroalkyl groups onto these C–H bonds with high activity (4,070 total turnovers, TTN) and selectivity (>99% ee). Notably, complementary regioselectivity can be achieved using an alternative enzyme, P411-PFA-(S). In Chapter 3, I report the first carbene transferase, P411-ACHF, which can transfer an α-cyanocarbene to arene C–H bonds of N-substituted benzenes. Chemodivergent C(sp²)–H and C(sp³)–H functionalization can be achieved using P411-ACHF and P411-PFA. Additionally, structural studies revealed an unprecedented backbone carbonyl flip within the long I-helix of P411-PFA, which may suggest how these enzymes have evolved to bind and activate diazo compounds for carbene transfer reactions. In Chapter 4, I discuss the efforts I took toward stabilizing an interesting but unstable P450, CYP3A4. This enzyme exhibits large active site volume and high substrate promiscuity and therefore can be a great candidate to develop late-stage carbene and nitrene transferases. I adopted consensus sequence mutagenesis and predicted five mutations which have the potential to have the strongest beneficial effects on improving CYP3A4's thermostability. In summary, this thesis work addresses the urgent need for expansion of the current enzymatic C–H functionalization reaction scope and the development of more sustainable and selective C–H functionalization catalysts which can be synthetically useful.